Behavior simulator

ABSTRACT

A simulator of human behavior includes logic circuitry which is selectively adjustable to represent human characteristics on a relative value scale. Encoded representations of human situational stimuli are inputted to the simulator through a card reader. The cards have pictorial representations of objects or scenes, sounds and people or beings thereon. They are made of a transparent material so that the visual representations on a number of cards can be viewed simultaneously when they are placed in the card reader. Visual output indicators represent a plurality of different behavioral responses to the input stimuli. The output responses range between an aggressive response and a retreat response. The input stimuli are connected through the logic circuitry to selectively actuate different ones of the output responses.

United States Patent 1191 Viemeister 1451 July 31,1973

[ BEHAVIOR SIMULATOR [76] Inventor: Peter E. Viemeister, 14 Baywood Ln., Bayport, N.Y. 11705 22 Filed: Feb. 3, 1972 211 Appl. No.: 223,113

U.S. Cl. 35/22 R Int. Cl. G09b 9/00 Field of Search 35/22 R, 9 D, 24 C,

[56] References Cited UNITED STATES PATENTS 2,928,189 3/1960 Molner et al. 35/22 R 3,067,524 12/1962 Parker 35/9 D ABSTRACT A simulator of human behavior includes logic circuitry which is selectively adjustable to represent human characteristics on a relative value scale. Encoded representations of human situational stimuli are inputted to the simulator through a card reader. The cards have pictorial representations of objects or scenes, sounds and people or beings thereon. They are made of a transparent material so that the visual representations on a number of cards can be viewed simultaneously when they are placed in the card reader. Visual output indicators represent a plurality of different behavioral responses to the input stimuli. The output responses range between an aggressive response and a retreat response. The input stimuli are connected through the logic circuitry to selectively actuate different ones of the output responses.

l3 Claims, 20 Drawing Figures DETERMINE wi'mu. l2 PM: 1. CONSCIOUS CONSCIOUS common us 16 ASSOCIATNE MEMORY CLASS'FY Mains CLASSIFY PARANOIA CLASSIFY mum: we FULL THREAT swam. Livz s gig? have I' 24 21 25 @MA ken-nu. ASSIFY OPTIMISM DEPRESSDN CLASSlFY r29 ATTllUDESHRELEVANCE LEVEL TDFF'CULTY 32 30 3| RESPONSE RESPONSE DETERMINE ATTnunEs my oer: Mme Manama-LEW t i gagg rwgu 36 v 1 40 V sneer 1 PAIENIEU JUL 3 I I973 ETIT-T SIIEEI 01 INITIAL PHYSICA IL} W DETERMINE PHY SICAL CONDITION CONDIT DETERMINE CONSCIOUS ION INITIAL CONSCIOUS S'I'A'LUS I6 STIMULI CLASSIFY ,S'I'IMULI IMPACT CATATO- NIA I EVEL CLASSIFY ATTENTIVENESS NAT INTIVI RECOGNIZE ASSOCIATNE MEMORY CLASSIFY FIGURE SYMBOL NEEDS LEVELS CLASSIFY NEEDS FULL- FILMENT OPPTY NEED FILL ATTILU DE 5 CLASSIFY RELEVANCE INTERA DETERMINE OPTIONS ATTITUDES RE SYNBOL FIGURESIIF CTI ON DEPRESSION CLASSIFY PARANOIA LEVEL a* THREAT LEVE L 24 OPTIMISM LEVEL CLASSIFY DIFFICULTY EA 3% Reasormamz OU'FILULT ANXIETY LEVEL CHALLENGE DETERMINE INTENTION OPTIONS SELEC RESPONSE ASSIVE SYMBOLOGY INPUT U OUTPUT CI PROCESS [3 FILE ODISPLAY ADJUSTABLE PARAMETER 'ETEIT'f A PATENIEU JUL3I ms MEI 02 0F GIN SWITCH PAIENIEU 3, 748 750 SHEET 0'4 HF 17 B c D E I i .C!

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TO NI PAIENIED JUL 3 1 I973 SHEET 05 0F DORMANT XYZ.

EXHAUSTEO I 8 I I I I l PHYSICAL STATUS SELECTOR PDQ SWITCH PAIENIEDJULSI ms 74 750 sum as 0F 17 EC DE.

CONSCIOUSNESS SELECTOR SWITCH DREAMING DRUNK PAIENIEmum I973 SHEET 07 OF GIVE o u N 0 s NO HELP 0 FIRE CARD READER SNARL O ANIMALQ AUTHORITY ATHER MOTHE PATENIEUJuL a 1 ms SHEET 09 0F .cqwmIP m2 PATENIE Jum ma S EET 10 0F PATENIEUJM I ms SHEET 15 0F PAIENI'E JUL 3 I mm sum 7 or NEED NTH PRIORITY '4TH PRIORITY NEED NEED

IST PRIORITY 2ND PRIORITY 3RD PRIORITY 1 BEHAVIOR SIMULATOR BACKGROUND OF THE INVENTION This invention relates to human personality simulators and more particularly to a simulator suitable for teaching and demonstrating psychological and behavioral science principles, for research and analysis of the impact of personality characteristics and disorders upon behavior, for diagnosing the personality characteristic producing a particular type of behavior. Electronic computers have been used in the field of psychology, psychiatry, and the behavioral sciences to score tests, count answers, and select and/or print from a repertory of pre-stored' statements.

As an example, US. Pat. No. 3,570,146 Golden describes a system. for automatically testing applicants by including projecting means for sequentially displaying test questions or a scene or situations to which the question relates. US. Pat. No. 3,579,869 Hewitt describes electronic logic circuitry for determining the correctness of students answers. While systems such as these are particularly useful is performing clerical tasks in education,'there is a requirement in the behavioral sciences for a system which will simulate the interaction of the human personality with external stimuli and which will represent the expected human response in a large number of situations.

The principles of analysis of human behavior have been widely discussed, but these principles have never been applied to a human personality simulator. An example of papers which discuss some of the principles of human behavioral model is: A Cybernetic Model of Human Change and Growth", David A. Kolb, working paper, Alfred P. Sloan School of Management, Massachusetts Institute of Technology, 1971. The concept of analyzing interactive systems is discussed in Principles of Systems, Jay W. Forrester, Massachusetts Institute of Technology, Cambridge, Massachusetts, 1968.

SUMMARY OF THE INVENTION In accordance with this invention, a human personality simulator is based on the principles that the human personality is a complex, but single, overall system composed of subsystems that interact with each other. The categories or types of personality subsystems are the same for every individual. However, each subsystem parameter of one individual is tuned uniquely. An individuals unique personality is the result of the interaction of these uniquely tuned subsystems. While the foregoing principles are not universally accepted, I have found that they are very useful premises and the simulator of this invention is based'upon these principles. The simulator represents'human personality with a finite number of parameters of behavioral conditions, needs, traits, attitudes and emotions. Each condition, need, trait, attitude or emotion is defined in terms of a relative scale or'relative value system such a more than normal or much less than normal".'In one particular embodiment of the invention, each value of condition, need, trait, attitude or emotion is represented by a multiposition switch and the value is representated by a relative position of each switch.

In accordance with another aspect of this invention, input stimuli are represented pictorially on precoded cards which are inserted into the simulator. The response of the simulator is directly related to the specific input stimuli. Thesestimuli, in the particular embodiment, are categorized into three classes: beings or persons, statements or sounds, and objects or scenes. The simulator of this embodiment accepts up to three stimuli simultaneously. The simulator will accept any one statement or sound, and/or anyone object or scene, and/or any one person or being simultaneously.

In from a to the stimuli, one of a number of visual output response indications is energizd. In a particular embodiment the outputs are classified-into five categories which range from positive response to a retreat response. In addition to providing an output of the ultimate behavioral response, the simulator'also provides indications which provide an insight into the interim conclusions of the perception process. For example, these interim output indicators include the specifying of the degree of attentiondirected to the stimuli, the relevance of the stimuli, whether the stimuli situation is perceived as a threat or as an offer, a classification of the degree of challenge or difficulty posed by the stimuli situation and the intensity of the will of the individual to respond to the stimuli. Appropriately labeled visualindicators are used for these interim outputs.

The stimuli are applied to the logic circuitry which includes the switches which represent the particular personality parameters as being more or less than average. In a particular embodiment, each of the parameters is represented on a three point scale although it will be understood that this principle can be enlarged upon to accommodate a five, seven, nine or even greater number of points on thescale. The more continuous the scale, the better the simulation; Further, these scales may be calibrated by matching actual human subject reactions to the identical stimuli in controlled test situations. I

The logic circuitry of this invention includes sequential decision tree branching switches, whiehare adjustable. One particularly advantageous feature of this circuitry is that it is arranged so that the simulator is insensitive to stimuli that are solely of a visual nature if the initial condition of the simulator is set to a position in which the subject is asleep. The principle of hierarchy is manifested by the simulator. For example, if the applied stimuli evokes intense fear, then other needs, attitudes, or considerations are irrelevant and are bypassed so that the response is determined primarily by the condition of fear or the need for survival.

One of the logiccircuits which is particularly advantageous is the negator circuit. This circuit is normally on and is turned off when inhibited by another signal. Appropriate use of this type of logic produces great advantages in the personality simulator, which will be discussed subsequently.

In accordance with another important aspect of the invention, the simulator will produce an output response only if the applied stimuli has attracted attention in much the same way that a human reacts to stimuli only after the stimuli has attracted the attention of the human. For example, merely showing an object to a sleeping person elicits no reaction because the person is inattentive. Similarly, showing an object to the simulator that is asleep elicits no reaction. In the particular embodiment of the simulator three levels of attentiveness are provided: Attentive, aware and inattentive. The intensity of the stimuli is coded on the stimuli cards. This intensity alters the state of consciousness of the simulator by energizing a different circuit. Provision is made for the operator to select the initial or base physical and consciousness status, but these initial conditions are then altered by the intensity of the stimuli. For example, the initial setting may be dormant (physical) and asleep (consciousness). A purely visual stimuli such as aview of a book would have no effect but a strong stimuli such as a shouted message will wake the simulator and change the condition to dull and drowsy.

In accordance with another aspect of this invention the simulator can be adjusted to incorporate personality aberrations or abnormalities such as paranoia, depression, anxiety, manic depression and catatonia. An abnormality is a distortion in thought processes that causes a shift from normal perception or evaluation. Paranoia, for example, heightens suspicion. Therefore, the simulator of this invention reduces the amount of trust and interprets offers as being ambiguous, and ambiguous situations as threats. The abnormality of depression, for example, shifts optimism toward pessimism in the logic circuitry and the final output.

The foregoing and other objects, features and advantages of the invention will be better understood from the following more detailed description, appended claims and drawings.

DESCRIPTION OF THE DRAWINGS FIG. 1 is a flow sheet depicting the simulator conceptual process.

FIG. 1A shows the flow sheet symbology;

FIG. 2 shows examples of the stimuli cards;

FIG. 3 shows the switch bank forming a part of the card reader;

FIG. 4 shows a cross-section of the card reader;

FIG. 5 is a perspective view of the simulator showing the general arrangement of the device;

FIGS. 6 show the manner in which FIGS. 6A-6M fit together to form a schematic diagram of the simulator, and

FIG. 7 shows a modification which includes simple electronic hierarchal logic.

DESCRIPTION OF'A PARTICULAR EMBODIMENT Flow Sheet, FIG. 1

Referring to FIG. 1 the flow sheet summarizes the process by which the simulator makes an appropriate output response to an input stimuli. The input of stimuli is indicated at 1 1. As indicated at 12 these are classified as to their impact. For example, the impact of a visual stimuli will be different from that of a sound stimuli and both will be different from the condition of no input stimuli.

The input stimuli may change the physical condition as indicated at 13 or the conscious condition as indicatcd at 14. These conditions are initially manually set as indicated at 15 and l6.

Output 17 visually indicates the physical condition which will be recognized, as indicated at 23. The level of attentiveness energizes the associative memory inputs which are then applied to three circuits which elassify the inputs at 24, 26, and 28.

For example, the inputs are classified as to a threat level, indicated at 24. This threat level may be modified for example by inputting a paranoia" level at 25. The interim output 24A visually indicates the threat level.

At 26, the inputs are classified as to figure symbols. For example, if the stimuli includes a being the signal is directed to needs that are pertinent to beings in general at 27. Similarly, if the stimuli includes a being, a signal also proceeds to 35.

Need levels are adjustable as indicated at 27. For example, if the simulated personality has a high need for affiliation at 27, and if the applied stimuli include a being, then there is a signal from 26 and there exists an opportunity to fulfill a need, 28. Similarly at 28, if there is a high need for nourishment at 27 and if there is a signal from 23 that indicates that the applied stimuli includes a representation of food, there exists an opportunity to fulfill a need at 28.

At 30 the inputs are classified as to degree of relevance. Attitudes toward fulfillment of needs are adjustable at 32 and modifythe degree of relevance. For example, if the simulated personality has a strong attitude for self gratification, and there is opportunity to fulfill a need, the situation is classified as Important. Interim visual output indications of the degree of relevance is provided at 33.

Signals from 30 and 29 are combined at 36 to determine intention options. The determination is modified by the level of anxiety and the attitude towards challenge at 38 of the simulated personality. Interim visual output indications of intentionality are provided at 39.

The inputs passing through 24 are classified as to degree of difficulty, at 29. The level of difficulty can be modified by adjusting the optimism level at 31. Interim visual output indications of the degree of difficulty are provided at 34.

The inputs passing through 26 are also classified to determine interaction options at 35. Interaction options are modified by the adjustment of attitudes re symbol figures as indicated at 378 and these attitudes, in turn are influenced by the sex of the simulated personality which is adjustable as indicated at'37A. For example, if the applied stimuli includes a Being who is represented as an attractive young woman and the sim ulated personality is a male who hates the opposite sex, the interaction options are thereafter limited to hostile or unfriendly responses.

Finally, the output response is selected by the simulator as indicated at 40. Signals from 35 and 36 are combined, and modified by moods and attitudes which are adjustable at 40A. The physical energy level, from 13, modifies the-intensity of the response. Any one of five output indications is possible in the simulator under discussion and these are indicated at 41.

Input Stimuli Cards and Card Reader, FIGS. 24

FIG. 2 shows cards 50, 51 and 52. Each card has machine sensible codes or tabs 53-58, which are encoded representations of situational stimuli. FIG. 3 shows a set of leaf switches in the card reader. These switches are selectively actuated by the tabs on the cards. For example when the card 50 is inserted in the card reader the tab 53 actuates switch A, the tab 54 actuates switch 

1. A variable personality simulator comprising: machine sensible encoded representations of human environmental stimuli, input means for reading said encoded representations of human environmental stimuli, output means indicating a particular behavioral response to said stimuli, and a plurality of adjustable logic means, each logic means being selectively adjustable to represent human characteristics on a relative value scale, the encoded representation of said stimuli being applied through said logic means to selectively actuate particular output means.
 2. The simulator recited in claim 1 wherein said input means include: a card reader responsive to perturbations in encoded cards to convert said machine sensible codes into electrical signals representing memory associated with the environmental stimuli denoted by the cards.
 3. The simulator recited in claim 2 wherein said machine sensible encoded representations of human environmental stimuli are cards representing different objects or scenes, different persons or beings, and different statements or sounds each having diFferent machine sensible codes and wherein said card reader includes a plurality of switches which are selectively actuated when different cards are inserted into said card reader.
 4. The simulator recited in claim 3 wherein each of said cards is made of a transparent material and wherein each card has a pictorial representation of an object or scene, person or being, or statement or sound thereon so that a plurality of the visual representations can be viewed through the transparent cards when they are inserted in said card reader.
 5. The simulator recited in claim 1 wherein said logic means includes a plurality of decision tree logic circuits, said encoded representations of stimuli being applied through said decision tree logic circuits to said output means.
 6. The simulator recited in claim 1 wherein said adjustable logic means includes: a physical status selector switch having a plurality of positions each representing the physical condition of the subject being simulated, the energization for said output means being applied through the positions of said physical status selector switch so that the output means which is energized will be determined in part by the position of said physical status selector.
 7. The simulator recited in claim 6 further comprising: an indicator connected to each position of said physical status switch, each indicator providing a visual indication of the physical status of the subject being simulated.
 8. The simulator recited in claim 1 wherein said adjustable logic means includes a consciousness selector switch having a plurality of positions each indicating a particular condition of consciousness of the subject being simulated, the energization for said output means being applied through said consciousness selector switch so that the output means which is energized will be determined in part by the position of said consciousness selector.
 9. The simulator recited in claim 8 further comprising: an indicator connected to each position of said consciousness selector switch, each indicator providing a visual indication of the conscious state of the subject being simulated.
 10. The simulator recited in claim 1 wherein said output means includes a plurality of visual indicators each representing a different behavioral response including an aggressive response, a positive response, a passive response, a refusal response and a retreat response.
 11. The simulator recited in claim 10 further comprising: a card reader having a plurality of switches which are selectively actuated by perturbations on cards inserted therein, a physical status selector having a plurality of positions each representing the physical condition of the subject being simulated, the energization for said output means being applied, a consciousness selector having a plurality of positions each indicating a particular condition of consciousness of the subject being simulated, energization for said output means being connected through said physical status selector, said consciousness selector and said card reader switches to selectively energize one of said output indicators.
 12. The system recited in claim 11 wherein said adjustable logic means comprises: a plurality of multiple position switches each having positions representing at least a high, neutral, or low parameter of human fears, loves, needs, emotional conditions and attitudes, the energization for said output means connected through said multiple position switches so that energization of said output means is dependent upon the position of said switches.
 13. The system recited in claim 1 wherein said adjustable logic means includes priority circuits each adjustable to assign a relative priority to certain of said human characteristics. 